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18520145ElectricMachinesandControlVol.18No.5May2014123221.3158002.1500803.276800:为设计交联聚乙烯(XLPE)绝缘高压直流电缆的结构,在实验基础上总结出进口高压直流电缆XLPE绝缘材料的电导特性方程,利用COMSOLMultiphysics软件通过电场和热场耦合仿真计算了电缆在不同负荷下的电场分布。研究表明,在电场强度较低和较高时,进口高压直流电缆XLPE绝缘材料的电导率随温度变化明显,电场强度变化几乎不对其产生影响;在某一电场强度范围内,温度和电场强度的改变均会使XLPE的电导率发生明显变化,该场强范围随温度而变化;所设计高压直流电缆在两种敷设环境下100%负荷时电场分布均匀;在电缆传输电流较大时,电缆XLPE绝缘内的温度梯度增大,电缆绝缘外表面处电场强度最大。基于有限元法的多物理场耦合仿真计算是研究XLPE绝缘高压直流电缆电场分布的有效手段。:高压直流电缆;交联聚乙烯;有限元;模拟仿真;电场TM247A1007-449X201405-0019-05SimulationofelectricalfielddistributionofXLPEinsulatedHVDCcableYEXin-hong1HANBao-zhong2HUANGQing-qiang3ZHAOHong2YANGJia-ming21.NingboDongfangCableLimitedbyShareLtdNingbo315800China2.KeyLaboratoryofEngineeringDielectricandItsApplicationMinistryofEducationSchoolofElectricalandElectronicEngineeringHarbinUniversityofScienceandTechnologyHarbin150040China3.RizhaoPowerSupplyCorporationofShandongElectricPowerCorporationRizhao276800ChinaAbstractInordertodesignthestructureofcross-linkedpolyethyleneXLPEinsulatedhighvoltagedi-rectcurrentHVDCcabletheelectricallyconductivecharacteristicequationofimportedXLPEinsula-tionmaterialsforHVDCcableisderivedbasedonexperimentalresultsandtheelectricalfielddistribu-tionofcableunderdifferentloadsiscalculatedthroughelectro-thermalfiledcouplingsimulationbyusingtheCOMSOLMultiphysicssoftware.TheresearchresultsshowthattheelectricalconductivityofimportedXLPEinsulationmaterialsforHVDCcableissensitivetotemperaturevariationandfreetochangeinelec-tricalfieldstrengthwhentheelectricalfieldstrengthislowerorhigher.Thechangeintemperatureande-lectricalfiledstrengthcanleadtoremarkablechangeofelectricalconductivityofXLPEinsomerangeofelectricalfieldstrengththatdependsontemperature.TheelectricalfielddistributioninsidethedesignedHVDCcableisuniformunder100%ofloadattwolayingconditions.AstransportcurrentishigherthetemperaturegradientinsideHVDCinsulationcableincreasesandtheelectricalfieldstrengthofoutsidesurfaceofinsulationcableismaximal.Thesefindingsindicatethatthemulti-physicalfieldcouplingsimu-lationbasedonthefiniteelementmethodisaneffectivewaytoinvestigatetheelectricalfielddistributionofXLPEinsulatedHVDCcable.Keywordshighvoltagedirectcurrentcablecross-linkedpolyethylenefiniteelementsimulatione-lectricalfiled2013-05-21:国家自然科学基金重点项目(51337002);国家863计划项目课题(2013AA050102);哈尔滨市科技创新人才研究专项资金项目(优秀学科带头人)(2012RFXXG079):叶信红(1968—),男,高级工程师,研究方向为高压电缆结构设计与制造;韩宝忠(1970—),男,教授,博士生导师,研究方向为高性能聚合物电介质材料;黄庆强(1988—),男,助理工程师,研究方向为高电压与绝缘技术;赵洪(1955—),男,教授,博士生导师,研究方向为纳米复合电介质理论及测试技术;杨佳明(1984—),男,博士研究生,讲师,研究方向为纳米复合电介质理论及测试技术。:韩宝忠0、、、1-2。。XLPE、、、3-6。XLPE2100km320kV。XLPE3、。XLPE20205000km7。XLPEXLPE、、XLPE。20XLPEXLPE。XLPECOMSOLMultiphysics250kVXLPE。1XLPEXLPE8E=U0rlnRrc1ErV/mU0VrcmRm。1。XLPE22XLPE9γ=γ0eaθ2E=U0BrB-1RB-rBc3B=aθc-θslnRrc。4γ00℃XLPES/mγθ℃XLPES/maθc℃θs℃。3B<1。XLPE3。XLPE。22.11GT-7014-P10CW2175℃15MPa230min310℃/min50℃4100mm、0.2mm5DMJ-45050mm624h。02182.21。屏蔽箱皮安表直流电源1Fig.1Diagramofstructureoftestingsystemforelectricalconductivityofsamples30℃、40℃、50℃、600℃70℃10h30℃、40℃、50℃、60℃70℃。33.1XLPE1lnγ=aθ+lnγ0。5lnγθ。0.22mmXLPE2kV5kV2。2kV5kVe-28e-29e-30e-31e-32e-33e-34电导率(S·m-1)3040506070温度/℃2XLPEFig.2RelationshipcurvebetweentemperatureandelectricalconductivityofXLPEunderconstantvoltage2lnγθ2a。3.2XLPE10-11γ=AEβ6Aβ。β=0β>0β。6lgγ=lgA+βlgE。77lgγlgElgγlgEβA。XLPE3。30℃40℃50℃60℃70℃10-1310-1410-1510-16电导率(S·m-1)0.1110电场强度(kV·mm-1)3XLPEFig.3RelationshipcurvebetweenelectricalconductivityofXLPEandelectricalfieldstrength3XLPE0.4~30kV/mmXLPE6。3.3XLPE23XLPEXLPEXLPE。XLPEXLPEXLPE。3.13.2XLPEγ=CθeaθEβθ。823XLPE4kV/mmXLPE4kV/mm。125130≤θ<40γ=1.38×10-28.74×e0.21θ×E1.694000≤E<3.55×107×0.99θγ=10-16.52+0.084θ10E≥3.55×107×0.99θ。240≤θ<60γ=5.08×10-28.09×e0.14θ×E1.6114000≤E<1.64×108×0.95θγ=10-14.24+0.027θ12E≥1.64×108×0.95θ。360≤θ≤70γ=8.80×10-51.56×e1.03θ×E5.2-0.06θ134000≤E<1.14×1036.74×0.37θ15.2-0.06θγ=10-13.82+0.02θ14E≥1.14×1036.74×0.37θ15.2-0.06θ。4XLPE250kVXLPE4。1-线芯;2-绕包半导电双面阻水带;3-导体屏蔽;4-XLPE绝缘;5-绝缘屏蔽;6-缓冲阻水带;7-金属护套;8-防腐层;9-PE护套;10-垫层;11-铠装;12-外护套。1234567891011124250kVXLPEFig.4DiagramofstructureofXLPEinsulatedhigh-voltageDCcableof250kV70℃1640A1400A。XLPE1600mm20.3mm1.7mm18mm1.2mm1mm2.7mm。COMSOLMultiphysics100%70℃56。0.050.040.030.020.010-0.01-0.02-0.03-0.0414.1741514.814.614.414.21413.813.613.413.2132.507%6×10-13-0.04-0.0200.020.04(a)1%640%A-0.04-0.0200.020.04(b)1%400%A14.7041514.814.614.414.21413.813.613.413.2132.262×10-130.050.040.030.020.010-0.01-0.02-0.03-0.045XLPEFig.5DistributionofelectricalfieldinsideXLPEinsulatedhigh-voltageDCcable14.1514.114.051413.9513.913.8513.813.7513.713.6513.613.55电场强度/(kV·mm-1)0.0280.030.0320.0340.0360.0380.040.0420.044与线芯中心轴距离/m(a)1%640%A14.714.614.514.414.314.214.11413.913.813.713.613.513.413.3电场强度/(kV·mm-1)0.0280.030.0320.0340.0360.0380.040.0420.044与线芯中心轴距离/m(b)1%400%A6Fig.6DistributionofelectricalfieldalongcableradiusdirectioninsideXLPEinsulation2218560.9450.980。1640A1400A1。1640A1400A10.55℃7.74℃。51XLPE。2XLPE。3XLPE。4XLPE。1.J.201232137-12.WENJialiangWURuiPENGChangetal.AnalysisofDCGridProspectsinChinaJ.ProceedingsoftheCSEE201232137-12.2SOODVK.-M.20081-10.3WENDTV.C//2011201124-32.4JACOB